U.S. patent application number 12/943586 was filed with the patent office on 2011-05-12 for quarter turn locking mechanism.
This patent application is currently assigned to MEDICINELODGE, INC. DBA IMDS CO-INNOVATION. Invention is credited to Joshua A. Butters, Carlyle J. Creger, Nicholas Slater.
Application Number | 20110110716 12/943586 |
Document ID | / |
Family ID | 43974268 |
Filed Date | 2011-05-12 |
United States Patent
Application |
20110110716 |
Kind Code |
A1 |
Slater; Nicholas ; et
al. |
May 12, 2011 |
QUARTER TURN LOCKING MECHANISM
Abstract
Apparatus and methods are disclosed for securely, yet
releasably, connecting separate parts. A shaft engages a
cooperating socket to form a connection capable of sustaining
service loads. The shaft has a protruding pin which slides within a
slot in the socket to guide the shaft into locked engagement with
the socket. The shaft also has a cantilever body which wedges into
a tapered region in the socket to frictionally bind the shaft and
socket together.
Inventors: |
Slater; Nicholas; (Chandler,
AZ) ; Butters; Joshua A.; (Chandler, AZ) ;
Creger; Carlyle J.; (Wellsville, UT) |
Assignee: |
MEDICINELODGE, INC. DBA IMDS
CO-INNOVATION
Logan
UT
|
Family ID: |
43974268 |
Appl. No.: |
12/943586 |
Filed: |
November 10, 2010 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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61259722 |
Nov 10, 2009 |
|
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Current U.S.
Class: |
403/348 |
Current CPC
Class: |
A61F 2220/0025 20130101;
A61F 2002/30426 20130101; F16B 21/04 20130101; F16B 2200/10
20180801; Y10T 403/7005 20150115; A61F 2/4684 20130101 |
Class at
Publication: |
403/348 |
International
Class: |
F16B 21/02 20060101
F16B021/02 |
Claims
1. A system, comprising: a shaft, the shaft comprising: a first
center axis, wherein the shaft extends along the first center axis,
a tip end, a first pin that protrudes from the shaft proximate the
tip end, wherein the first pin is generally orthogonal to the first
center axis, a slit that extends through the tip end and a portion
of the shaft, wherein the slit is generally orthogonal to the first
pin; and a socket, the socket comprising: a second center axis,
wherein the socket extends along the second center axis, an inner
diameter, an open end, a second end opposite the open end, wherein
at least one dimension of the second end is smaller than the inner
diameter, a tapered region between the inner diameter and the
second end, and a first slot that projects into a side wall of the
socket, wherein the first slot comprises a starting end at the open
end and a terminal end spaced apart from the open end, wherein the
terminal end is rotationally offset around the side wall from the
starting end.
2. The system of claim 1, wherein the shaft is selectively movable,
relative to the socket, between: an unlocked position in which the
tip end is in the inner diameter, and the first pin is in the
starting end; and a locked position in which the tip end is wedged
in the tapered region so as to at least partially pinch the slit,
and the first pin is in the terminal end, wherein the shaft is
selectively movable between the unlocked and locked positions by
rotating the shaft within the socket so that the first pin slides
along the first slot between the starting and terminal ends,
wherein the shaft is fabricated from a material comprising an
elastic limit, wherein, when the tip end is wedged in the tapered
region so as to pinch the slit completely closed at the tip end,
stresses in the shaft are less than the elastic limit.
3. The system of claim 2, wherein the shaft is selectively movable,
relative to the socket, to an intermediate position in which the
tip end makes incipient contact with the tapered region, the slit
is unpinched, and the first pin is in the first slot between the
starting and terminal ends, wherein, as the shaft moves from the
intermediate position to the locked position, a frictional locking
force builds between the shaft and the socket to bind the shaft and
socket together, and, as the shaft moves from the locked position
to the intermediate position, the frictional locking force
diminishes.
4. The system of claim 1, wherein the socket comprises a second
slot like the first slot, wherein the second slot is rotated around
the second center axis relative to the first slot.
5. The system of claim 4, wherein the shaft comprises a second pin
like the first pin, wherein the second pin is rotationally
positioned around the first center axis relative to the first pin,
wherein the shaft is selectively movable, relative to the socket,
between: an unlocked position in which the tip end is in the inner
diameter, and the first and second pins are in starting ends of the
first and second slots, respectively; and a locked position in
which the tip end is wedged in the tapered region so as to at least
partially pinch the slit, and the first and second pins are in
terminal ends of the first and second slots, respectively.
6. The system of claim 1, wherein the shaft further comprises: an
outer diameter; flattened portions along the outer diameter where
the slit extends through the shaft; and a flattened region around
the first pin, wherein the tip end is circumferentially
beveled.
7. The system of claim 1, wherein the first slot comprises: a
starting portion that extends parallel to the second center axis; a
terminal portion that extends substantially perpendicular to the
second center axis; and a helical portion between the starting and
terminal ends.
8. The system of claim 1, wherein a portion of the first slot is
spaced farther apart from the open end than is the terminal
end.
9. A system, comprising: a shaft, the shaft comprising: a first
longitudinal axis, wherein the shaft extends along the first
longitudinal axis, an outer diameter, and a tip end, wherein the
tip end is split to comprise a plurality of cantilever bodies,
wherein one of the cantilever bodies comprises a first tab, wherein
the first tab protrudes outwardly beyond the outer diameter; and a
socket, the socket comprising: a second longitudinal axis, wherein
the socket extends along the second longitudinal axis, an inner
diameter, an open end, a second end opposite the open end, wherein
at least one dimension of the second end is smaller than the inner
diameter, a tapered region inside the socket between the inner
diameter and the second end, and a first slot in a side wall of the
socket, wherein the first slot comprises a mouth at the open end
and a terminus spaced apart from the open end, wherein the terminus
is angularly offset around the side wall from the mouth.
10. The system of claim 9, wherein the shaft is selectively
movable, relative to the socket, between: an unlocked position in
which the tip end is in the inner diameter, and the first tab is in
the mouth; and a locked position in which the tip end is wedged in
the tapered region so as to at least partially compress the
cantilever bodies together, and the first tab is in the terminus,
wherein the shaft is selectively movable between the unlocked and
locked positions by rotating the shaft within the socket so that
the first tab slides along the first slot between the mouth and
terminus, wherein the shaft is fabricated from a material
comprising an elastic limit, wherein, when the tip end is wedged in
the tapered region so that the cantilever bodies touch together at
the tip end, stresses in the shaft are less than the elastic
limit.
11. The system of claim 10, wherein the shaft is selectively
movable, relative to the socket, to an intermediate position in
which the tip end makes incipient contact with the tapered region,
the cantilever bodies are uncompressed, and the first tab is in the
first slot between the mouth and terminus, wherein, as the shaft
moves from the intermediate position to the locked position, a
frictional locking force develops between the shaft and the socket
to bind the shaft and socket together, and, as the shaft moves from
the locked position to the intermediate position, the frictional
locking force wanes so that the shaft and socket are mutually
separable.
12. The system of claim 9, wherein the socket comprises a second
slot like the first slot, wherein the second slot is rotated around
the second longitudinal axis from the first slot, wherein the shaft
comprises a second tab like the first tab, wherein the second tab
is rotated around the first longitudinal axis from the first tab,
wherein, when the shaft and the socket are operatively assembled,
the first tab engages the first slot and the second tab engages the
second slot.
13. The system of claim 9, wherein the tip end is circumferentially
beveled.
14. The system of claim 9, wherein the first slot comprises: a
starting portion that extends parallel to the second longitudinal
axis; a terminal portion that extends substantially perpendicular
to the second longitudinal axis; and a helical portion between the
mouth and terminus.
15. The system of claim 9, wherein a portion of the first slot is
spaced farther apart from the open end than is the terminus.
16. A locking mechanism, comprising: a shaft comprising an outer
diameter and a working end, wherein the working end is
circumferentially beveled, wherein the working end comprises a
plurality of resilient prongs, wherein each one of the prongs
carries a tab, wherein each one of the tabs projects outwardly from
the outer diameter; and a socket comprising an inner diameter, an
open end, and a longitudinal axis, wherein the socket extends along
the longitudinal axis, wherein the open end comprises a plurality
of grooves in the inner diameter, wherein each one of the grooves
follows a path between a starting point and a terminal point,
wherein the terminal point is offset from the starting point along
the longitudinal axis and around the inner diameter, wherein the
socket further comprises a tapered constriction distant from the
open end.
17. The locking mechanism of claim 16, wherein the plurality of
tabs and the plurality of grooves are arranged in complementary
circular arrays.
18. The locking mechanism of claim 16, wherein the shaft is
selectively movable, relative to the socket, between: an unlocked
position in which the working end is in the inner diameter, and the
tabs are in the grooves proximate the starting points; and a locked
position in which the working end is wedged in the tapered
constriction so as to at least partially deflect the prongs, and
the tabs are in the grooves proximate the terminal points, wherein
the shaft is selectively movable between the unlocked and locked
positions by rotating the shaft within the socket so that the tabs
slide along the grooves between the starting and terminal
points.
19. The locking mechanism of claim 18, wherein the shaft is
selectively movable, relative to the socket, to an intermediate
position in which the working end makes incipient contact with the
tapered constriction, the prongs are undeflected, and the tabs are
in the grooves between the starting and terminal points, wherein,
as the shaft moves from the intermediate position to the locked
position, a frictional locking force develops between the shaft and
the socket to bind the shaft and socket together, and, as the shaft
moves from the locked position to the intermediate position, the
frictional locking force wanes.
20. The locking mechanism of claim 16, wherein each one of the
grooves comprises: a starting portion that extends parallel to the
longitudinal axis; a terminal portion that extends substantially
perpendicular to the longitudinal axis; and a helical portion
between the starting and terminal points.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the benefit of the filing date of
U.S. Application No. 61/259,722, which was filed on Nov. 10, 2009,
is entitled QUARTER TURN LOCKING MECHANISM FOR SURGICAL INSTRUMENT
CONNECTION, and carries Attorney's docket no. IWO-1 PROV. The
contents of U.S. Application No. 61/259,722 are hereby incorporated
by reference as part of this application.
BACKGROUND OF THE INVENTION
[0002] The present disclosure relates to interconnections for
securely yet releasably connecting separate components. In certain
embodiments, quarter turn locking mechanisms are disclosed.
Specific embodiments are disclosed in the context of a spinal
system comprising a trial implant and an inserter tool.
SUMMARY OF THE INVENTION
[0003] The present disclosure sets forth components, systems, kits,
and methods for securely yet releasably connecting separate parts.
In an embodiment, a spinal trial implant inserter tool and a spinal
trial implant are securely, yet releasably, connected. The
connection is capable of sustaining intraoperative loads as the
spinal trial implant is maneuvered relative to the spine. The
connection may be connected and disconnected quickly and easily
when desired. The connection relies upon cooperating features on
the tool and the trial. The geometry of the cooperating features is
relatively insensitive to dimensional variation, therefore
relatively larger manufacturing tolerances may be specified without
sacrificing acceptable function.
BRIEF DESCRIPTION OF THE DRAWINGS
[0004] FIG. 1 is a perspective view of a spinal trial implant and
an inserter tool;
[0005] FIG. 2 is a perspective detail view of a distal end of the
inserter tool of FIG. 1;
[0006] FIG. 3A is a perspective cephalad-lateral view of the spinal
trial implant of FIG. 1; FIG. 3B is a perspective caudal-lateral
view of the spinal trial implant of FIG. 1; and FIG. 3C is an
anterior view of the spinal trial implant of FIG. 1;
[0007] FIG. 4 is a perspective view of the spinal trial implant and
inserter tool of FIG. 1, with the inserter tool partially inserted
into the trial;
[0008] FIG. 5 is a lateral view of the spinal trial implant and
inserter tool of FIG. 1, with the inserter tool fully locked to the
spinal trial implant;
[0009] FIG. 6 is a cross-sectional view of the spinal trial implant
and inserter tool of FIG. 5;
[0010] FIG. 7A is a perspective view of a shaft; FIG. 7B is a top
view of the shaft of FIG. 7A; FIG. 7C is an end view of the shaft
of FIG. 7A; and FIG. 7D is a front view of the shaft of FIG.
7A;
[0011] FIG. 8A is a top perspective view of a socket; FIG. 8B is a
top view of the socket of FIG. 8A; FIG. 8C is an end view of the
socket of FIG. 8A; FIG. 8D is a front view of the socket of FIG.
8A; FIG. 8E is a front perspective view of the socket of FIG. 8A;
and FIG. 8F is a cross sectional view of the socket of FIG. 8A
taken along the section line indicated in FIG. 8D;
[0012] FIG. 9A is a perspective view of the shaft of FIG. 7A in an
unlocked position relative to the socket of FIG. 8A; FIG. 9B is a
front view of the shaft and socket of FIG. 9A; FIG. 9C is a cross
sectional view of the shaft and socket of FIG. 9A, taken along the
section line shown in FIG. 9B; FIG. 9D is a top view of the shaft
and socket of FIG. 9A; and FIG. 9E is a cross sectional view of the
shaft and socket of FIG. 9A, taken along the section line shown in
FIG. 9D;
[0013] FIG. 10A is a perspective view of the shaft of FIG. 7A in an
intermediate position relative to the socket of FIG. 8A; FIG. 10B
is a front view of the shaft and socket of FIG. 10A; FIG. 10C is a
cross sectional view of the shaft and socket of FIG. 10A, taken
along the section line shown in FIG. 10B; FIG. 10D is a top view of
the shaft and socket of FIG. 10A; and FIG. 10E is a cross sectional
view of the shaft and socket of FIG. 10A, taken along the section
line shown in FIG. 10D;
[0014] FIG. 11A is a perspective view of the shaft of FIG. 7A in a
locked position relative to the socket of FIG. 8A; FIG. 11B is a
front view of the shaft and socket of FIG. 11A; FIG. 11C is a cross
sectional view of the shaft and socket of FIG. 11A, taken along the
section line shown in FIG. 11B; FIG. 11D is a top view of the shaft
and socket of FIG. 11A; and FIG. 11E is a cross sectional view of
the shaft and socket of FIG. 11A, taken along the section line
shown in FIG. 11D;
[0015] FIG. 12A is a perspective view of another shaft, with two
cantilever bodies and one pin; FIG. 12B is a perspective view of
yet another shaft, with four cantilever bodies and two adjacent
pins; FIG. 12C is a perspective view of yet another shaft, with
four cantilever bodies and two opposite pins; FIG. 12D is a
perspective view of yet another shaft, with four cantilever bodies
and four pins; FIG. 12E is a perspective view of yet another shaft,
with five cantilever bodies and one pin; and FIG. 12F is a
perspective view of yet another shaft, with six cantilever bodies
and three pins;
[0016] FIG. 13A is a perspective view of another socket, with one
slot having a starting portion, a helical portion, and a terminal
portion; FIG. 13B is a perspective view of yet another socket, with
three slots like the slot in FIG. 13A; FIG. 13C is a perspective
view of yet another socket, with two slots, each having a starting
portion, a helical portion, and a terminal portion; FIG. 13D is a
perspective view of yet another socket, with two slots, each having
a helical portion and a terminal portion; FIG. 13E is a perspective
view of yet another socket, with two slots, each having a starting
portion and a helical portion; FIG. 13F is a front view of the
socket of FIG. 13A; FIG. 13G is a front view of the socket of FIG.
13C; FIG. 13H is a front view of the socket of FIG. 13D; and FIG.
13J is a front view of the socket of FIG. 13E;
[0017] FIG. 14A is a perspective view of yet another socket, with
two slots, each having a helical portion; FIG. 14B is a perspective
view of yet another socket, with two slots like the slots in FIG.
14A extending partially through a side wall of the socket; FIG. 14C
is a perspective view of yet another socket, with two slots, each
having a starting portion and a terminal portion; FIG. 14D is a
perspective view of yet another socket, with two slots, each having
a starting portion and a terminal portion; FIG. 14E is a front view
of the socket of FIG. 14A; FIG. 14F is a front view of the socket
of FIG. 14C; and FIG. 14G is a front view of the socket of FIG.
14D.
DETAILED DESCRIPTION
[0018] While certain embodiments have been shown and described in
detail below, it will be clear to the person skilled in the art
upon reading and understanding this disclosure that changes,
modifications, and variations may be made and remain within the
scope of the components, systems, kits, and methods described
herein. Furthermore, while various features are grouped together in
the embodiments for the purpose of streamlining the disclosure, it
is appreciated that features from different embodiments may be
combined in a mix and match fashion.
[0019] The following description and accompanying drawings are
offered by way of illustration only. In particular, while the
present disclosure sets forth an embodiment in the context of
surgical instruments, one of skill in the art will appreciate that
the components, systems, kits, and methods may be applicable
outside the realm of surgical instruments or the field of medicine
altogether.
[0020] Not every feature of each embodiment is labeled in every
figure in which that embodiment appears, in order to keep the
figures clear. Similar reference numbers (e.g., those that are
identical except for the first numeral) are used to indicate
similar features in different embodiments.
[0021] Standard medical planes of reference and descriptive
terminology are employed in this specification. A sagittal plane
divides a body into right and left portions. A mid-sagittal plane
divides the body into equal right and left halves. A coronal plane
divides a body into anterior and posterior portions. A transverse
plane divides a body into superior and inferior portions. Anterior
means toward the front of the body. Posterior means toward the back
of the body. Superior means toward the head. Inferior means toward
the feet. Medial means toward the midline of the body. Lateral
means away from the midline of the body. Axial means toward a
central axis of the body. Abaxial means away from a central axis of
the body.
[0022] Referring to FIG. 1, an embodiment of a locking mechanism is
shown in the context of a system for spinal surgery. An inserter
tool 10 is shown connected to a trial implant 60 by means of a
connection mechanism 8. The trial 60 includes a mock implant body
portion 61 which may be positioned within an intervertebral disc
space in order to determine the proper size for a spinal implant
(not shown) for permanent implantation. The tool 10 includes a
handle 11. The tool 10 is used to hold and manipulate the trial 60
as the trial 60 is inserted into the intervertebral disc space. The
connection mechanism 8 between the trial 60 and the tool 10 may
have cooperating features on the trial 60 and the tool 10 which
releasably couple the trial 60 and the tool 10. The connection
mechanism 8 may be subjected to service loads which are oriented
with respect to one or more of three mutually perpendicular axes.
The service loads may act along an axis, such as tensile or
compressive loads, or around an axis, such as a torque load.
Furthermore, service loads may be a combination of axial and/or
torque loads along and/or around any or all of the three mutually
perpendicular axes. The three mutually perpendicular axes may be
aligned with respect to the structure of the trial 60 and/or the
tool 10 or with respect to anatomic planes and/or axes of
reference.
[0023] Referring to FIG. 2, the tool 10 may have a shaft 12 with a
longitudinal axis 14 centered in the shaft 12. The axis 14 may be
described as an axis of revolution or axis of radial symmetry of
the basic shaft 12.
[0024] The shaft 12 may have an outer diameter 16, a tip end 18,
and a first pin 20. The tip end 18 may also be described as a
working end of the shaft 12, in the sense that tip end 18 may have
features to connect the tool 10 to the trial 60. The first pin 20
may be proximate the tip end 18. The first pin 20 protrudes
outwardly beyond the outer diameter 16 of the shaft 12. The first
pin 20 may protrude normal to the outer diameter 16 and orthogonal
to the axis 14. The first pin 20 may be cylindrical.
[0025] The tip end 18 may be split into a plurality of cantilever
bodies 22, 24. The cantilever bodies 22, 24 are so named because
they function as cantilever flex beams, as will be described
presently in more detail. The cantilever bodies 22, 24 may also be
described as resilient prongs which extend alongside axis 14. The
tip end 18 may be split into two cantilever bodies 22, 24 by slit
26. Slit 26 may also be described as a slot or notch.
[0026] Slit 26 is shown extending through the tip end 18 and along
a portion of the shaft 12. Slit 26 may extend completely across the
shaft 12 in a direction orthogonal to the first pin 20. Slit 26 may
have a uniform width over most of its length. In other words, slit
26 may provide a uniform separation, or gap, between cantilever
bodies 22, 24 over most of their length. For a given material, the
width of slit 26 may be designed so that cantilever bodies 22, 24
provide a desired resistance to pinching the slit 26 closed at the
tip end 18. The width of slit 26 may also step down, or become
narrower, proximate the tip end 18, so as to form opposing raised
bosses 28, 30 between the cantilever bodies 22, 24 at the tip end
18. The bosses 28, 30 may serve to protect the shaft 12 from
overload conditions during use. More specifically, for a given
material, the width of slit 26 at the tip end 18 between the bosses
28, 30 may be selected so that the shaft 12 experiences only
elastic deformation, even when slit 26 is squeezed completely
closed at the tip end 18 so that the bosses 28, 30 touch. In other
words, stresses in shaft 12 remain below an elastic limit of the
shaft 12 material because bosses 28, 30 serve as physical stops to
prevent excess deflection of the cantilever bodies 22, 24.
[0027] The first pin 20 may be situated on a first cantilever body
22. Shaft 12 may include a second pin 32 like the first pin 20. The
second pin 32 may be in a position that is rotated around the axis
14 relative to the first pin 20, so that the first pin 20 and the
second pin 32 are arranged in a circular array around the axis 14.
In FIG. 2, the second pin 32 is in a position that is rotated 180
degrees from the first pin 20, so that the pins 20, 32 are
symmetrically arranged around the axis 14 on opposite sides of the
shaft 12.
[0028] The shaft 12 may have flattened portions 34, 36, 38, 40
along the outer diameter 16 where the slit 26 breaks through the
shaft 12, as illustrated in FIGS. 2 and 4. The flattened portions
34, 36, 38, 40 soften, or break, edges along the intersection of
slit 26 and outer diameter 16. The flattened portions 34, 36, 38,
40 also make the cantilever bodies 22, 24 narrower.
[0029] The shaft 12 may have flattened regions 42, 44 around the
first and second pins 20, 32, as illustrated in FIGS. 2 and 4.
[0030] The tip end 18 of shaft 12 may have a circumferentially
bevel 46. The bevel 46 softens, or breaks, an edge where the outer
diameter 16 terminates at the tip end 18. The bevel 46 also tapers
the tip end 18.
[0031] The shaft 12 may be fabricated from polymers, metals,
ceramics, composites, glass, wood, or other materials according to
the requirements of a particular application. The shaft 12 may be
fabricated from a combination of materials, so that each feature of
the shaft 12 is fabricated from a material suitable to the
particular requirements of the individual feature. In the context
of surgical instruments, implants, and systems, it is contemplated
that the shaft 12 may be fabricated from polymers such as
polyetheretherketone (PEEK), acetal, or ultra high molecular weight
polyethylene (UHMWPE), or from metals comprising iron, chrome,
titanium, nickel, or molybdenum.
[0032] Referring to FIGS. 3A-C and 6, the trial 60 may have a tube
or socket 62 with a longitudinal axis 64 centered in the socket 62.
The axis 64 may be described as an axis of revolution or axis of
radial symmetry of the basic socket 62.
[0033] The socket 62 may have an inner diameter 66, an open end 68,
a second end 70, a tapered region 72, a side wall 74, and a first
slot 76. The inner diameter 66 extends between the open end 68 and
the tapered region 72. The second end 70 is opposite the open end
68, thus in this embodiment, the second end 70 is deep within the
socket 62. The second end 70 may be closed, or blind. The tapered
region 72 is inside the socket 62, between the inner diameter 66
and the second end 70, and distant from the open end 68. The
tapered region 72 may be oriented to form a tapered constriction,
such that the second end 70 is smaller than the inner diameter
66.
[0034] The first slot 76 may project through the side wall 74 of
the socket 62.
[0035] The first slot 76 may have a starting end 78 at the open end
68 and a terminal end 80 spaced apart from the open end 68. The
starting end 78 provides an opening, or mouth, through the open end
68 into the first slot 76. The terminal end 80 may be a blind end,
or terminus. The terminal end 80 has a combined offset from the
starting end 78, with a first component of the offset in a
direction parallel to the axis 64, and a second component of the
offset in an angular direction around the axis 64. In the
embodiment of FIGS. 3A-C, the angular offset is about 90 degrees,
although other angular offsets are contemplated.
[0036] The first slot 76 may have a starting portion 88 that
extends parallel to the axis 64 and helical portion 92 between the
starting end 78 and the terminal end 80. The helical portion 92
spirals around the side wall 74 of the socket 62 in a manner
similar to a screw thread.
[0037] The socket 62 may include a second slot 94 like the first
slot 76. The second slot 94 may be in a position that is rotated
around the axis 64 relative to the first slot 76. Thus, the first
slot 76 and the second slot 94 may be arranged in a circular array
around the axis 64. In FIGS. 3A-C, the second slot 94 is in a
position that is rotated 180 degrees from the first slot 76, so
that the slots 76, 94 are symmetrically arranged around the axis 64
on opposite sides of the socket 62.
[0038] With reference to FIGS. 2 and 3A-C, one may appreciate that
the pins 20, 32 and the slots 76, 94 are advantageously arranged in
complementary circular arrays.
[0039] The socket 62 may be fabricated from polymers, metals,
ceramics, composites, glass, wood, or other materials according to
the requirements of a particular application. The socket 62 may be
fabricated from a combination of materials, so that each feature of
the socket 62 is fabricated from a material suitable to the
particular requirements of the individual feature. In the context
of surgical instruments, implants, and systems, it is contemplated
that the socket 62 may be fabricated from polymers such as
polyetheretherketone (PEEK), acetal, or ultra high molecular weight
polyethylene (UHMWPE), or from metals comprising iron, chrome,
titanium, nickel, or molybdenum.
[0040] An alternate embodiment shaft 112 is shown in FIGS. 7A-D.
Shaft 112 is similar to shaft 12 of tool 10, but shaft 112 only
includes features which cooperate with a socket to form a
connection mechanism. Shaft 112 may thus be described as a
subcomponent or design element which could be incorporated into the
design of a more fully featured component. For example, shaft 112
may be incorporated onto a working end of a shaft of a nut driver
for nuts incorporating a cooperating socket (described below). As
another example, shaft 112 may be incorporated onto a stem of a
tibial trial component for removably attaching modular trial stems
incorporating a cooperating socket.
[0041] Shaft 112 may have an axis 114, an outer diameter 116, a tip
end 118, two pins 120, 132, two cantilever bodies 122, 124, a slit
126, two bosses 128, 130, four flattened portions 134, 136, 138,
140, two flattened regions 142, 144, and a bevel 146. All of these
features are identical to the corresponding features described for
shaft 12.
[0042] FIGS. 12A-F illustrate additional shaft embodiments, each of
which shares at least some features in common with shafts 12, 112.
The following descriptions disclose distinguishing characteristics
of each embodiment.
[0043] Shaft 212 of FIG. 12A may have a longitudinal center axis
214, two cantilever bodies 222, 224, a slit 226, and a single pin
220. Pin 220 is carried by cantilever body 222, and slit 226 is
orthogonal to pin 220.
[0044] Shaft 312 of FIG. 12B may have a longitudinal center axis
314, four cantilever bodies 322, 323, 324, 325, two slits 326, 327,
and two pins 320, 332. Pin 320 is carried by cantilever body 322
and pin 332 is carried by cantilever body 323, so that pins 320,
332 are asymmetrically arranged about axis 314. Slits 326 and 327
are identical, and are oriented at 45 degree angles to pins 320,
332. Shaft 312 lacks a flattened portion, comparable to flattened
portion 34, along any of the cantilever bodies 322, 323, 324,
325.
[0045] Shaft 412 of FIG. 12C may have a longitudinal center axis
414, four cantilever bodies 422, 423, 424, 425, two slits 426, 427,
and two pins 420, 432. Slit 426 is similar in design to slit 26.
Slit 427 terminates beside pins 420, 432 so that slit 427 is much
shorter than slit 426. Slit 426 is orthogonal to pins 420, 432,
while slit 427 is parallel to pins 420, 432. Pin 420 is carried at
the juncture of cantilever bodies 422, 423 and pin 432 is carried
at the juncture of cantilever bodies 424, 425, so that pins 420,
432 are symmetrically arranged about axis 414. Shaft 412 lacks a
flattened portion, comparable to flattened portion 34, along any of
the cantilever bodies 422, 423, 424, 425.
[0046] Shaft 512 of FIG. 12D may have a longitudinal center axis
514, four cantilever bodies 522, 523, 524, 525, two slits 526, 527,
and four pins 520, 521, 532, 533. Pin 520 is carried by cantilever
body 522, pin 521 is carried by cantilever body 523, pin 532 is
carried by cantilever body 524, and pin 533 is carried by
cantilever body 525, so that pins 520, 521, 532, 533 are
symmetrically arranged about axis 514. Slits 526 and 527 are
identical, and are oriented at 45 degree angles to pins 520, 532.
Shaft 512 lacks a flattened portion, comparable to flattened
portion 34, along any of the cantilever bodies 522, 523, 524,
525.
[0047] Shaft 612 of FIG. 12E may have a longitudinal center axis
614, five cantilever bodies 622, 623, 624, 625, 629, five slits
626, 627, 631, 635, 637, and a single pin 620. Pin 620 is carried
by cantilever body 622. Slits 626, 627, 631, 635, 637 are
identical, extending only halfway through shaft 612. Slits 626, 627
are oriented at 36 degree angles to pin 620, and all five slits
626, 627, 631, 635, 637 are symmetrically arranged about axis 614.
Shaft 612 lacks a flattened portion, comparable to flattened
portion 34, along any of the cantilever bodies 622, 623, 624, 625,
629.
[0048] Shaft 712 of FIG. 12F may have a longitudinal center axis
714, six cantilever bodies 722, 723, 724, 725, 729, 739, three
slits 726, 727, 731, and three pins 720, 721, 732. Pin 720 is
carried by cantilever body 722, pin 721 is carried by cantilever
body 724, and pin 732 (obscured by remainder of shaft 712) is
carried by cantilever body 729, so that pins 720, 721, 732 are
symmetrically arranged about axis 714. Shaft 712 lacks a flattened
portion, comparable to flattened portion 34, along any of the
cantilever bodies 722, 723, 724, 725, 729, 739.
[0049] Any of the pins described herein may alternatively protrude
from the corresponding shaft in a direction other than normal to
the corresponding outer diameter and/or in a direction other than
orthogonal to the corresponding axis. Any of the pins described
herein may alternatively have a non-circular cross sectional shape,
such as triangle, oval, elliptical, polygonal, teardrop, or lobed.
Such cross sectional shapes may cause the pin to resemble a tab,
ear, flange, or post instead of a cylinder.
[0050] The tip end of a shaft may have a single cantilever body, or
may be split into two or more cantilever bodies according to the
needs of a particular application. FIGS. 12B-F show embodiments
having different numbers of cantilever bodies. The tip end may have
slits that extend partially or entirely across the shaft in order
to form the desired number of cantilever bodies. FIG. 12E shows an
embodiment with slits that extend partially across shaft 612, while
FIGS. 12A-D and F show embodiments with slits that extend entirely
across the corresponding shaft.
[0051] Pins may be arranged around a shaft in a symmetric or
asymmetric circular array. FIGS. 12C, D, and F illustrate
symmetrical pin arrays, while FIG. 12B illustrates an asymmetric
pin array. Pins may all be alike, so that a shaft may have a single
array of pins. Alternatively, a shaft may have a plurality of
arrays, wherein each array is characterized by a different pin
configuration. For example, one such embodiment may include two pin
configurations which alternate around an outer diameter of a shaft.
Each of the pins may be situated on a separate cantilever body, in
a manner reminiscent of FIG. 12D. Alternatively, each cantilever
body may carry a plurality of pins. In a further alternative,
selected cantilever bodies may lack pins altogether, as illustrated
in FIGS. 12A, B, E, and F.
[0052] Alternative shaft embodiments may employ edge break
configurations that differ from flattened portions 34, 36, 38, 40.
These may include features such as chamfers, bull noses, radii,
fillets, or variable edge blends. The edge break may be confined to
a zone proximate the tip end of a shaft. Edge break may be
unnecessary in certain embodiments, such as those shown in FIGS.
12B-F.
[0053] A shaft may optionally include a longitudinal through hole
or cannulation.
[0054] Alternative shaft embodiments may employ edge break
configurations that differ from bevel 46. These may include
features such as a chamfer, bull nose, radius, fillet, or variable
edge blend. Edge break may be unnecessary in certain
embodiments.
[0055] An alternate embodiment socket 162 is shown in FIGS. 8A-F.
Socket 162 is similar to socket 62 of trial 60, but socket 162 only
includes features which cooperate with a shaft to form a connection
mechanism. Socket 162 may thus be described as a subcomponent or
design element which could be incorporated into the design of a
more fully featured component. By way of non-limiting example,
socket 162 may be incorporated on a working end of a shaft for a
screwdriver for use with screws incorporating shaft 112, or socket
162 may be formed into a broach for use with a broaching handle
incorporating shaft 112.
[0056] Socket 162 may have an inner diameter 166, an open end 168,
a second end 170, a tapered region 172, a side wall 174, a first
slot 176, a starting end 178, a terminal end 180, a starting
portion 188, a terminal portion 190, a helical portion 192, and a
second slot 194. All of these features are identical to the
corresponding features described for socket 62.
[0057] FIGS. 13A-J illustrate additional socket embodiments, each
of which shares at least some features in common with sockets 62,
162. The following descriptions disclose distinguishing
characteristics of each embodiment.
[0058] Socket 262 of FIGS. 13A and 13F may have a longitudinal
center axis 264 and a single slot 276. Slot 276 is identical to
slot 76. Slot 276 follows a path 282 between a starting end 278 and
a terminal end 280. The path 282 may extend between a starting
point 284 and a terminal point 286. The starting point 284 may be
at the starting end 278 or at a location outside the open end 268.
The terminal point 286 may be at or near the terminal end 280. The
terminal point 286 may be offset from the starting point 284 along
the longitudinal axis 264 and around the inner diameter 266, in
order to produce a desired combined offset for the terminal end
280. The path 282 may describe a tool path followed by a cutter
during fabrication of the slot 276.
[0059] Socket 362 of FIG. 13B may have a longitudinal center axis
364 and three slots 376, 394, 395. Each of the slots 376, 394, 395
is identical to slot 76. The slots 376, 394, 395 are symmetrically
arranged around axis 364.
[0060] Socket 462 of FIGS. 13C and 13G may have a longitudinal
center axis 464, an open end 468, and two identical slots 476, 494
symmetrically arranged around axis 464 on opposite sides of socket
462. Slot 476 extends between a starting end 478 and a terminal end
480. Slot 476 follows a path 482 between a starting point 484 and a
terminal point 486. The path 482 resembles path 282, but a portion
of the path 482 between the starting point 484 and the terminal
point 486 is spaced farther from the open end 468 than is the
terminal point 486, as is best appreciated in FIG. 13G. As a
result, slot 476 extends along the socket 462 past the location of
the terminal end 480, and then turns back to reach the terminal end
480.
[0061] Socket 562 of FIGS. 13D and 13H may have a longitudinal
center axis 564 and two identical slots 576, 594 symmetrically
arranged around axis 564 on opposite sides of socket 562. Slot 576
extends between a starting end 578 and a terminal end 580. Slot 576
may have a terminal portion 590 like terminal portion 90 and a
helical portion 592 like helical portion 92. However, slot 576
lacks a starting portion like starting portion 88. Instead, helical
portion 592 extends all the way to the starting end 578 along path
582.
[0062] Socket 662 of FIGS. 13E and 13J may have a longitudinal
center axis 664 and two identical slots 676, 694 symmetrically
arranged around axis 664 on opposite sides of socket 662. Slot 676
extends between a starting end 678 and a terminal end 680. Slot 676
may have a starting portion 688 like starting portion 88 and a
helical portion 692 like helical portion 92. However, slot 676
lacks a terminal portion like terminal portion 90. Instead, helical
portion 692 extends all the way to the terminal end 680 along path
682.
[0063] FIGS. 14A-G illustrate additional socket embodiments, each
of which shares at least some features in common with sockets 62,
162. The following descriptions disclose distinguishing
characteristics of each embodiment.
[0064] Socket 762 of FIGS. 14A and 14E may have a longitudinal
center axis 764 and two identical slots 776, 794 symmetrically
arranged around axis 764 on opposite sides of socket 762. Slot 776
extends between a starting end 778 and a terminal end 780. Slot 776
may have a helical portion 792 like helical portion 92. However,
slot 776 lacks a starting portion like starting portion 88. Slot
776 also lacks a terminal portion like terminal portion 90.
Instead, helical portion 792 extends all the way to the terminal
end 780 along path 782.
[0065] Socket 862 of FIG. 14B may have a longitudinal center axis
864 and two identical slots 876, 894 symmetrically arranged around
axis 864 on opposite sides of socket 862. Slots 876, 894 are
identical to slots 776, 794. However, slots 876, 894 project only
partially through a side wall 874 of socket 862, so that socket 862
possesses a smooth, continuous outer surface. This embodiment may
afford greater strength to slots 876, 894 in service, and may be
less likely to snag on surrounding objects.
[0066] Socket 962 of FIGS. 14C and 14F may have a longitudinal
center axis 964 and two identical slots 976, 994 symmetrically
arranged around axis 964 on opposite sides of socket 962. Slot 976
extends between a starting end 978 and a terminal end 980. Slot 976
may have a starting portion 988 like starting portion 88 and a
terminal portion 990 like terminal portion 90. However, slot 976
lacks a helical portion like helical portion 92. Instead, starting
portion 988 blends directly into terminal portion 990 along path
982.
[0067] Socket 1062 of FIGS. 14D and 14G may have a longitudinal
center axis 1064, an open end 1068, and two identical slots 1076,
1094 symmetrically arranged around axis 1064 on opposite sides of
socket 1062. Slot 1076 extends between a starting end 1078 and a
terminal end 1080. Slot 1076 resembles slot 976. However, a portion
of slot 1076 lies farther from the open end 1068 than does the
terminal end 1080, as is best seen in FIG. 14G.
[0068] In alternative embodiments, a socket may have a hole or
cannulation (not shown) extending from a second end of the socket.
The hole or cannulation may go partially or completely through the
socket. The second end may simply be an intersection, or edge,
between a tapered region within the socket and a hole extending
farther into the socket.
[0069] Slots and their corresponding paths may be configured in
various ways. A terminal portion of a slot may make an angle of
precisely 90 degrees with respect to a corresponding axis. FIGS.
3A-C, 8D, 13F, and 14F show examples of this type of terminal
portion. Alternatively, it may be advantageous for a terminal
portion to make an acute angle with respect to the axis. For
example, the terminal portion may hook back toward the open end of
the socket, as is shown in FIGS. 13G and 14G. Starting and terminal
portions of a slot may be separated by one or more intervening
portions, such as a helical portion (FIGS. 13A and F) or a
non-helical ramp. Alternatively, the starting portion may
transition directly to the terminal portion so that the slot more
closely resembles an "L" or a dogleg configuration, as illustrated
in FIGS. 14 C, D, F, and G. It is further contemplated that a
starting portion could combine with dual terminal portions to form
a "T" configuration.
[0070] In further embodiments, a slot may be made up of multiple
portions or segments so that a shaft and a socket may be locked
together with varying degrees of security, or in multiple
orientations and positions.
[0071] In other embodiments, a slot may terminate in a recessed
portion into which a pin must be forced against friction. An
embodiment with this characteristic may provide additional locking
force to couple a shaft and a socket together.
[0072] In alternate embodiments, a socket may have a plurality of
slots arranged in a circular array around a longitudinal center
axis of the socket. The plurality of slots may be arranged
symmetrically or asymmetrically. The slots may all be alike, so
that the socket may have a single array of slots. Alternatively,
the socket may have a plurality of arrays, wherein each array is
characterized by a different slot configuration. For example, one
such embodiment may include two slot configurations which alternate
around a side wall of the socket.
[0073] The number and arrangement of pins on a shaft need not
exactly match the number and arrangement of slots on a
corresponding socket. Rather, it is sufficient that the number and
arrangement of pins on the shaft coordinates with the number and
arrangement of slots on the socket to provide the desired number of
mating orientations between the shaft and the socket. By way of
non-limiting example, a shaft having only one pin may provide two
mating orientations with a socket having two slots. A shaft with
two pins may provide six mating orientations with a socket having
six slots. A shaft having a larger first pin and a smaller second
pin may provide one mating orientation with a socket having a
larger first slot and a smaller second slot.
[0074] The embodiment shown in FIGS. 1-6 is configured for assembly
of the shaft 12 to the socket 62. The inner diameter 66 of the
socket 62 is larger than the outer diameter 16 of the shaft 12,
such that the outer diameter 16 fits within the inner diameter 66.
The first and second slots 76, 94 are larger than the first and
second pins 20, 32, respectively, such that the first and second
pins 20, 32 fit within the first and second slots 76, 94,
respectively.
[0075] The shaft 12 is selectively movable, relative to the socket
62, between an unlocked position and a locked position. FIG. 4
illustrates the unlocked position. FIGS. 5-6 illustrate the locked
position. In the unlocked position, the shaft 12 and the socket 62
are freely separable. In the locked position, the shaft 12 and the
socket 62 are secured together sufficiently to resist service
loads. One can appreciate that the security of the locked position
for a specific application may be directly proportional to the
magnitude of service loads in that application.
[0076] In the unlocked position of FIG. 4, the axes 14, 64 are
substantially aligned, the tip end 18 is positioned in the inner
diameter 66, and the first pin 20 is positioned in the starting end
78, or mouth, of the first slot 76. In the embodiment of FIGS. 1-6,
the second pin 32 is also in a starting end of the second slot 94
in the unlocked position. In alternate embodiments comprising a
plurality of pins and slots, one can appreciate that some or all of
the pins may be in starting ends of corresponding slots.
[0077] In the locked position of FIGS. 5-6, the axes 14, 64 are
substantially aligned, the tip end 18 is wedged in the tapered
region 72 so as to at least partially pinch the slit 26 closed, and
the first pin 20 is in the terminal end 80, or terminus, of the
first slot 76. Thus, the cantilever bodies 22, 24 are at least
partially compressed together. The flattened portions 34, 36, 38,
40 provide relief across the incompressible width of the cantilever
bodies 22, 24 so that there is clearance with the tapered region
72. The bevel 46, if present, may be complementary to the tapered
region 72. In the embodiment of FIGS. 1-6, the second pin 32 is
also in a terminal end of the second slot 94. In alternate
embodiments comprising a plurality of pins and slots, one can
appreciate that some or all of the pins may be in terminal ends of
corresponding slots. Furthermore, the sort of relief provided by
flattened portions 34, 36, 38, 40 may not be necessary in
alternative embodiments with narrow cantilever bodies, such as
embodiments comprising three or more cantilever bodies.
[0078] Any material possesses inherent material properties.
Material properties may be modified through manufacturing processes
such as heat treatment, work hardening, pressure treatments, or
aging. By way of non-limiting example, a material may be
characterized by an elastic limit. The elastic limit is a stress at
which the material begins to experience plastic, or permanent,
deformation. At stresses below the elastic limit, the material
experiences elastic, or temporary, deformation which spontaneously
resolves as soon as applied forces are removed. For example, the
shaft 12 may be designed so that stresses in the shaft 12 due to
deformation of the cantilever bodies 22, 24 are less than the
elastic limit when the tip end 18 is wedged in the tapered region
72 so as to pinch the slit 26 completely closed at the tip end 18.
This may be accomplished by designing a specific clearance, or gap,
between bosses 28, 30, so that the bosses 28, 30 contact each other
and thereby prevent further deformation of the cantilever bodies
22, 24. Slit 26 may be advantageously designed in view of the
material properties resulting after completion of all applicable
manufacturing operations.
[0079] In the locked position, the shaft 12 and socket 62 are
secured together by frictional forces. At least some of the
frictional forces may result from elastic deformation of the
cantilever bodies 22, 24 when the tip end 18 wedges into the
tapered region 72.
[0080] A first frictional force may exist where the tip end 18 is
wedged into the tapered region 72. The cantilever bodies 22, 24
tend to resist being compressed together. Thus, the tip end 18
exerts a force against the tapered region 72, acting in a direction
generally normal to the contacting surfaces. This outward normal
force causes the first frictional force, which resists rotation of
the tip end 18 against the tapered region 72.
[0081] A second frictional force may exist where the first pin 20
rests within the terminal end 80 of the first slot 76. The second
frictional force may be related to the first frictional force. The
tip end 18 tends to resist wedging into the tapered region 72. At
least a portion of such resistance may act along the axes 14, 64 so
as to force the first pin 20 against a side of the first slot 76
opposite the tapered region 72, i.e., a side closer to the open end
68. The force between the first pin 20 and the side of the first
slot 76 acts in a direction generally normal to the contacting
surfaces. This axial normal force causes the second frictional
force, which resists sliding of the first pin 20 along the side of
the first slot 76. One can appreciate that a similar frictional
force may exist between other pins and slots in alternate
embodiments.
[0082] The second frictional force may alternatively be caused by
other interactions between features of the shaft 12 and the socket
62, such as wedging of the first pin 20 into an undercut, a
recessed region, or a tapered constriction proximate the terminal
end 80 of the first slot 76. Furthermore, additional frictional
forces may be present in alternative embodiments.
[0083] With reference to FIGS. 4-6, the shaft 12 is selectively
movable between the unlocked and locked positions by rotating the
shaft 12 within the socket 62 so that the first pin 20 slides along
the first slot 76 between the starting and terminal ends 78, 80. In
the present embodiment, clockwise rotation of the shaft 12 in the
socket 62 moves the shaft 12 from the unlocked position of FIG. 4
to the locked position of FIGS. 5-6. Counterclockwise rotation of
the shaft 12 in the socket 62 moves the shaft 12 from the locked
position of FIGS. 5-6 to the unlocked position of FIG. 4. In an
alternate embodiment, these rotational directions may be
reversed.
[0084] As the shaft 12 moves between the unlocked position and the
locked position, the first pin 20 slides along the first slot 76
between the starting and terminal ends 78, 80. Thus, the specific
configuration of the first slot 76 dictates the motion of the shaft
12 relative to the socket 62. By way of non-limiting example, the
starting portion 88 of the first slot 76 of FIGS. 4-6 guides the
shaft 12 into the socket 62 in a direction generally parallel to
the axes 14, 64. The starting portion 88 prevents rotation of the
pin 20 about the axes 14, 64. The helical portion 92 constrains the
shaft 12 to rotate clockwise about the axes 14, 64 and
simultaneously advance within the socket 62 in a direction
generally parallel to the axes 14, 64. The terminal portion 90
permits the shaft 12 to rotate clockwise about the axes 14, 64.
Axial advancement is prevented.
[0085] The shaft 12 may be selectively movable, relative to the
socket 62, to an intermediate position in which the tip end 18
makes incipient contact with the tapered region 72, the slit 26 is
uncompressed, the cantilever bodies 22, 24 are undeflected, and the
first pin 20 is in the first slot 76 between the starting and
terminal ends 78, 80. The intermediate position may be described as
a transitional position between the loose unlocked position and the
secure locked position.
[0086] As the shaft 12 moves from the intermediate position to the
locked position, one or more of the aforementioned frictional
forces builds between the shaft 12 and the socket 62 to bind the
shaft 12 and socket 62 together. As the shaft 12 moves from the
locked position to the intermediate position, the friction
diminishes so that the shaft 12 and socket are mutually
separable.
[0087] The embodiment shown in FIGS. 7-11 is configured so that
shaft 112 may be assembled, or connected, to socket 162. The inner
diameter 166 of the socket 162 receives the outer diameter 116 of
the shaft 112 with clearance. The slots 176, 194 of the socket 162
receive the pins 120, 132 of the shaft 112 with clearance.
[0088] The shaft 112 is selectively movable, relative to the socket
162, between an unlocked position, illustrated in FIGS. 9A-E, and a
locked position, illustrated in FIGS. 11A-E. In the unlocked
position, the shaft 112 and socket 162 are freely separable. In the
locked position, the shaft 112 and socket 162 are secured together
sufficiently to resist service loads. The security of the locked
position may be proportional to the magnitude of service loads for
a particular application.
[0089] In the unlocked position of FIGS. 9A-E, the axes 114, 164
are substantially aligned, the tip end 118 is positioned in the
inner diameter 166, and the first pin 120 is positioned in the
starting end 178, or mouth, of the first slot 176. In the
embodiment of FIGS. 9-11, the second pin 132 is also in a starting
end of the second slot 194 in the unlocked position. FIGS. 9C and
9E show mutually perpendicular cross sections through the shaft 112
and socket 162 in the unlocked position. It can be appreciated that
outer diameter 116 of shaft 112 is a clearance fit with inner
diameter 166 of socket 162, and that flattened portions 134, 136,
138, 140 provide additional clearance across the width of
cantilever bodies 122, 124.
[0090] In the locked position of FIGS. 11A-E, the axes 114, 164 are
substantially aligned, the tip end 118 is wedged in the tapered
region 172 so as to at least partially pinch the slit 126 closed,
and the first pin 120 is in the terminal end 180, or terminus, of
the first slot 176. Thus, the cantilever bodies 122, 124 are at
least partially compressed together. The flattened portions 134,
136, 138, 140 provide relief across the incompressible width of the
cantilever bodies 122, 124 so that there is clearance with the
tapered region 172. In the embodiment of FIGS. 9-11, the second pin
132 is also in a terminal end of the second slot 194. FIGS. 11C and
11E show mutually perpendicular cross sections through the shaft
112 and socket 162 in the locked position. It can be appreciated
that tip end 118 of shaft 112 is wedged within tapered region 172
of socket 162, slit 126 is pinched at least partially closed, and
flattened portions 134, 136, 138, 140 provide clearance across the
width of cantilever bodies 122, 124.
[0091] The shaft 112 is selectively movable between the unlocked
and locked positions by rotating the shaft 112 within the socket
162. Clockwise rotation of the shaft 112 in the socket 162 moves
the shaft 112 from the unlocked position of FIGS. 9A-E to the
locked position of FIGS. 11A-E. Counterclockwise rotation of the
shaft 112 in the socket 162 moves the shaft 112 from the locked
position of FIGS. 11A-E to the unlocked position of FIGS. 9A-E.
[0092] The shaft 112 may be selectively movable, relative to the
socket 162, to an intermediate position, illustrated in FIGS.
10A-E, in which the tip end 118 makes incipient contact with the
tapered region 172, the slit 126 is uncompressed, the cantilever
bodies 122, 124 are undeflected, and the first pin 120 is in the
first slot 176 between the starting and terminal ends 178, 180. In
the embodiment of FIGS. 9-11, the second pin 132 is also in a
similar location in the second slot 194. FIGS. 10C and 10E show
mutually perpendicular cross sections through the shaft 112 and
socket 162 in the intermediate position. It can be appreciated that
tip end 118 of shaft 112 has made incipient contact with tapered
region 172 of socket 162.
[0093] While the present disclosure has been made in the context of
a spinal system comprising a trial implant and an inserter tool,
the corresponding connection features described herein have a broad
range of applications. By way of non-limiting example, the
connection features may be applied to surgical trials, rasps,
handles, pilot cutters, awls, and mallets, and further applications
may be contemplated outside the medical field.
[0094] It should be understood that the present components,
systems, kits, apparatuses, and methods are not intended to be
limited to the particular forms disclosed. Rather, they are
intended to include all modifications, equivalents, and
alternatives falling within the scope of the claims. They are
further intended to include embodiments which may be formed by
combining features from the disclosed embodiments.
[0095] The claims are not to be interpreted as including
means-plus- or step-plus-function limitations, unless such a
limitation is explicitly recited in a given claim using the
phrase(s) "means for" or "step for," respectively.
[0096] The term "coupled" is defined as connected, although not
necessarily directly, and not necessarily mechanically.
[0097] The use of the word "a" or "an" when used in conjunction
with the term "comprising" in the claims and/or the specification
may mean "one," but it is also consistent with the meaning of "one
or more" or "at least one." The term "about" means, in general, the
stated value plus or minus 5%. The use of the term "or" in the
claims is used to mean "and/or" unless explicitly indicated to
refer to alternatives only or the alternative are mutually
exclusive, although the disclosure supports a definition that
refers to only alternatives and "and/or."
[0098] The terms "comprise" (and any form of comprise, such as
"comprises" and "comprising"), "have" (and any form of have, such
as "has" and "having"), "include" (and any form of include, such as
"includes" and "including") and "contain" (and any form of contain,
such as "contains" and "containing") are open-ended linking verbs.
As a result, a method or device that "comprises," "has," "includes"
or "contains" one or more steps or elements, possesses those one or
more steps or elements, but is not limited to possessing only those
one or more elements. Likewise, a step of a method or an element of
a device that "comprises," "has," "includes" or "contains" one or
more features, possesses those one or more features, but is not
limited to possessing only those one or more features. Furthermore,
a device or structure that is configured in a certain way is
configured in at least that way, but may also be configured in ways
that are not listed.
* * * * *